Abstract: The emerging electric model of the universe holds the key to understanding the causes of long and short-term climate variation. The pattern of variation has very specific characteristics, characteristics that match the behavior of a noisy electrical circuit. The electric model reveals that the Earth is indeed connected to a cosmic electrical circuit, a circuit that is subject to the kind of noise that could produce the patterns seen in the Earth’s temperature record.

Earth’s fractal temperature pattern

The past 420,000 years – the ice-age cycle

The most reliable long-term temperature record we have comes from ice core data. The charts presented here are based on data downloaded from the World Center for Paleoclimatology, Boulder. The Antarctic dataset comes from Vostok, and goes back 420,000 years. The Arctic dataset comes from Greenland, and goes back 50,000 years. Both datasets are useful up until about 1880 AD. Vostok temperatures are shown in red; Greenland temperatures are shown in green.

The temperatures shown for each dataset are expressed in degrees centigrade, relative to the dataset’s temperature in 1800 AD, which is shown as zero. The years are expressed as a calendar date, negative indicating BC. Only values up to 1800 AD are shown in these charts, so that we’ll be looking at natural climate variation, prior to any effects that might arise from industrial-era greenhouse gas emissions.

In this long-term record we see a fractal pattern – the same kind of pattern occurring on different scales. On the largest scale, we a sequence of first-tier temperature spikes of about 10° C, occurring with an irregular frequency of about 100,000 years. In between these spikes are ice ages, and the tops of the spikes give us our brief inter-glacial periods of about 10,000 years. On a smaller scale we see a similar pattern of second-tier spikes in the range of 2°–5°, occurring with a semi-regular frequency of about 10,000 years. As we’ll see in later charts, this fractal pattern, of semi-regular spikes, continues on ever-smaller timescales.

Pierre-Marie Robitaille, Ph.D., is a professor of radiology at The Ohio State University. He also holds an appointment in the Chemical Physics Program. In 1998, he led the design and assembly of the world’s first Ultra High Field MRI System. This brought on the need to question fundamental aspects of thermal physics, including ideas related to Kirchhoff’s Law of thermal emission, and more.

As the theory goes; some 14 billion years ago, there was “nothing” focalized in a single, highly-dense point. Then, that “nothing” exploded, hurling the ingredients for everything we see in the universe into existence. On paper, it sounds insane. Heck, its kind of IS insane, but we have several pieces of solid (but not irrefutable) evidence that show not only could it have happened this way, but that it probably did.

One such proof comes in the form of the “Cosmic Microwave Background Radiation,” (CMB or CMBR) the after-glow of the big bang, if you will. It gives us an opportunity to understand the very first moments following the creation of the universe, yet it also poses many tantalizing mysteries that threaten to unhinge the very fabric on which we believe the universe was formed.

Before we go into those, let’s first explore what the CMBR is. Amazingly, this story has a crappy start.

In 1965, before two scientists, Arno Penzias and Robert Wilson, started measuring radio signals as they bounced from balloon satellites for NASA’s “Project Echo,” they needed to take preventive measures to make sure the data they collected was completely incorruptible.

“Charged matter affecting matter of a different electrical potential”.

“SAFIRE is more like sailing, in that we are looking into the way that nature does things. We are not trying to force the plasma phenomena”

“We’re not trying to get the plasma to organize, but it likes to become organized under certain conditions.”

There is a video at point 24:30 where Childs shows the plasma. He says “it likes to form these tufts, we don’t understand them, but we’re looking at them, they become organized. Their fields are uniform and they like to be separated.”

“Some of the energy and the density that we have now are comparable to what we see in the sun, it’s pretty amazing.”

“This is controversial, I can’t really talk too much at this time yet, how we got this, but what I can say, if some of you are familiar with mass spectroscopy or digital gas analyzers, you’ll know what you’re looking at here; We started off with a chamber of pure hydrogen and we baked it out for a couple of days. Then what happened is, the chamber’s clean it’s purged, we put hydrogen in. Mass spec is saying you have pure hydrogen in the chamber, 100 per cent. We thought this is great . . . We introduced another gas, we got double layers formed. We let it sit in there and bake for a few hours, it was extremely stable . . . We added another gas, the moment the double layers disappeared and we got this [shows mass spectrometer reading] . . . Hydrogen dropped down from 100 per cent to 39 per cent and all these other elements formed.”

He mentions barium and titanium, they don’t know why they formed.

He then shows video of ‘double layers’ forming at about 27:30, then he shows how the energy suddenly concentrates. Slide states: “We were not trying to trap high energy photons and electrons comparable to the sun’s photosphere … but it does.”

Then he shows another video of something that he says has been patented: he states “This is a hollow anode, I will tell you that I’m actually putting deuterium and hydrogen as a mix through the core of the anode.”

“Some of you that are into cold fusion have a hard time getting atomic hydrogen. SAFIRE produces copius amounts of it”

“What we do is we put hydrogen into the hollow anode and we have a special material that the anode is made out of, it dissociates the H2 to H, and because it is positively charged we strip the electron and we actually have protons migrating from off the surface of the anode into the atmosphere”

He says there is no need for the magnetic fields to contain the plasma, it creates it’s own containment field, it wants to organize.

He says the SAFIRE plasma engine creates an environment to facilitate this self-organization.